RESUMO
The dephosphorylation of CTP, GTP, ITP, ATP, CDP, GDP, IDP and ADP was characterized by measuring the first-order rate constant (50 degrees; I = 0.1, NaClO4) in dependence on pH (2 to 10). Except with CTP and CDP, the reactions are significantly accelerated by Cu2+ and pass through pH optima. By computing the pH dependence of the distribution of the several species present in the nucleotide (NP) systems, it is shown that the most reactive species is Cu(NP). Cu(NP-H), where N(1) is deprotonated, is somewhat less reactive. In both types of complexes, a metal ion-nucleic base interaction, which is responsible for the increased reactivity, occurs, i.e., macrochelates involving the phosphate chains and the base moieties are formed. In accord herewith, CTP and CDP are rather stable as the coordination tendency of the cytosine moiety is small. Furthermore, in the ternary complexes Cu(2,2'-bipyridyl)(NP) and Cu-(2,2'-bipyridyl)(NP-H), where the formation of a macrochelate is inhibited, the nucleotides are protected. The structure-reactivity relationship is also evident with Cu(ITP)2- and Cu(IDP)- which exist only in part as macrochelates; hence, they are less reactive than for example Cu(ATP)2- or Cu(ADP)-. With the aid of the initial rate, vo = d[PO4(3-)]/dt, the rate laws of the ascending side of the pH optima were determined: vo = k[Cu(NP)]/[H+]. A reaction mechanism that includes an intermolecular attack of OH- at the terminal phosphate group is proposed. The descending side of the pH optimum is attributed to the formation of CU(NP)(OH) or Cu(NP-H)(OH), where the Cu2+-base interaction is insignificant. However, these hydroxy complexes are still somewhat faster dephosphorylated than the free nucleotides. This is attributed to an intramolecular attack of the bound OH- at the terminal phosphate group.